Systems and methods for dynamically navigating content

ABSTRACT

Methods and systems for dynamically navigating content are provided. An input to perform content navigation may be detected; in response, several selectable navigation settings are displayed, each navigation setting being associated with a navigation interval. An input indicating a selection of a navigation setting may be received and an input about a navigation amount may be received. Based on the navigation amount, navigation within the navigation interval is performed.

BACKGROUND

The present disclosure relates to media play systems and methods and,more particularly, to systems and methods related to media playoperations, such as shifting a current play position in content (e.g., amedia asset) that is being viewed.

SUMMARY

Audio and video media devices, such as dedicated recorders, televisions,and more recently handheld devices (e.g., smartphones and tablets) offertheir users the flexibility to perform various media contentmanipulations, offline (disconnected from Internet access) or online(while connected to the Internet, wirelessly or with wire). Benefitingfrom modern day technology advancements, media device users enjoyflexible media content (e.g., videos and audio books) consumption at,and during, a time of their choosing, at a location of their choosing,and with a media device of their choosing.

Media devices are ubiquitous, available on a variety of platforms andimplemented on and compatible with a variety of networks and electronicdevices. Continuously growing in application, it is no surprise thateach media device type features a distinct user experience. For example,a smart television or a digital recorder, in combination with a largescreen display, offers the consumer no less than a theater-like viewingexperience, yet a smart handheld device offers the consumer theconvenience of mobility. Where an audio player may not have or needgraphics features, a video player typically does. Where a large formfactor media player, such as a desktop computer, may be void oftouchscreen media content functionality, a small form factor mediaplayer, such as a smartphone, is nearly expected to have a touchscreenfeature.

Media content functionality, like a touchscreen seekbar for mediacontent skip operations, are among more recent electronic entertainmentdevice improvements offering the consumer flexibility and convenience torapidly navigate media content with a simple touch of the finger.Accordingly, different media device types offer a different userexperience, flexibility and convenience.

A conventional seekbar, for example, enables a user to navigate througha video/audio in a forward or backwards direction. The seekbar length isnot proportional to the length of audio/video. Instead, the seekbar'slength is the same for all video/audio content. It is relatively easy touse the seekbar for audio/video content with small duration whencompared to the ones with a long duration. This is particularly the casein small screen devices for content with a long duration. A usertypically has to be very careful, otherwise there may be excessive backand forth fine horizontal adjustment needed to navigate to the user'spreferred time point in the content. Sometimes such excessively fine,repetitive adjustment can lead to ergonomic problems like a pain in thewrist, etc. In other situations, a user may be holding a device in onehand and may have difficulty using that hand to navigate to the desiredlocation on the seekbar. Thus, there is a need for improved medianavigation tools for navigating to a desired play position and that isadapted to smaller display devices.

In some approaches described herein, a content navigation system createsdifferent navigation intervals within a content to assist the user inmore accurately navigating from a play position to a shifted playposition. In some embodiments, a navigation interval represents aportion only of the content in which navigation is permitted, that is tosay, the shifted play position can only be within that portion. Forexample, the content navigation system may detect an input from a user(e.g., using a touchscreen) for activating a media content navigationoperation (e.g., selecting a seekbar tool). In response to that input,the content navigation system generates for display on an interface(e.g., a screen of a smartphone, tablet or laptop) at least twoselectable navigation settings that can be selected by the user. Eachsetting is associated with a shifting limit value, the purpose of whichis to define, with a current play position of the content, a navigationinterval within the content. The navigation interval represents aportion of the content that is navigable during the media contentnavigation operation and the rest of the content will be excluded fromthat navigation operation. The shifting limit value can thus be chosento be different from a beginning or an end of the content. The twonavigation settings each have a different shifting limit value, suchthat two different navigation intervals within the content aredetermined. For instance, one of the navigation settings is associatedwith a shifting limit value of 5 min for fine control and the othernavigation setting with a shifting limit value of 1 h for coarsercontrol. The two settings offer two different options to provide animproved control over the content navigation operation. The contentnavigation system then receives an input, from the user, indicating aselection of one of the two navigation settings. The user thus has thechoice of being able to navigate only in the next (or previous) 5 min or1 h. To determine by how much the content is to be shifted, the contentnavigation system can be arranged to receive an input that represents anavigation amount (e.g., a physical 2-dimensional path within thedisplay interface or a physical 1-dimensional projection thereof,wherein the path typically represents a movement of a finger or apointer on the display interface). The content navigation system finallynavigates from a current position to a shifted position, using thenavigation amount, wherein the shifted position is within the navigationinterval of the selected navigation setting.

In some approaches described herein, the navigation internal isdetermined based on the current play position and the shifting limitvalue. In some embodiments, the boundaries of the navigation intervalmay be defined by a current play position (e.g., the play position whenthe content navigation system detects the input to perform the contentnavigation operation or when the content navigation system receives aninput indicating a selection of the navigation settings or thenavigation amount) and the current play position plus the shifting limitvalue, or the current play position minus the shifting limit value andthe current play position plus the shifting limit value, or even thecurrent play position minus the shifting limit value and the currentplay position. Therefore, the content navigation system provides animproved method to shift content in fast forward, fast backward, orboth. In some embodiments, a forward shifting limit value and a backwardshifting value may be used, so that the amount of content navigableforward is different from the amount of content navigable in reverse.The content navigation system can therefore adapt to the current playposition in the content and/or the needs of the user and the devicebeing used.

In some approaches, the time shifting value may be determined in variousway. In an embodiment, the shifting limit value is determined takinginto account the overall length of the content or the length of contentleft to watch or elapsed (so-called relative shifting limit value). Inanother embodiment the shifting limit value is an absolute value whichis independent of the overall length of the content (so-called absoluteshifting limit value). The relative shifting value may be defined as anyamount of time between a current play position and the end of thecontent or any amount of time of the overall length of the content (i.e.any amount of time of the content left to watch). For instance, thecontent navigation system may determine the shifting limit value to be asmall percentage (e.g., 5%) of the amount left to watch for a firstnavigation setting and a larger percentage (e.g., 50%) of the amountleft to watch for a second navigation setting. The first navigationsetting enables the viewer to navigate up to 5% of the content left towatch, while the second navigation setting enables the viewer tonavigate up to 50% of the content left to watch. For instance, theabsolute shifting limit value may be 1 min or 1 h. At least one of theshifting limit values may be relative while at least one of the shiftinglimit values may be absolute (for instance, 1 min, 1 h and 80%).

In some approaches described herein, the content navigation system alsotakes into account a scaling parameter to control the relationshipbetween the navigation amount and the amount of content that is beingshifted in the navigation interval. In particular, the contentnavigation system obtains a scaling parameter (e.g., an input from theuser), and that scaling parameter is used to translate the navigationamount to a navigation amount time within the navigation interval (e.g.,to equate the path to a time by which the play position is to beshifted). In an implementation, each selectable navigation setting isassociated with a scaling parameter, and receiving the input indicatingthe selection of the navigation setting causes the scaling parameter tobe utilized. The content navigation system may also determine scalingparameters such that the longer the navigation interval, the higher thescaling parameter. This enables similar navigation amounts (e.g., a 3-cmmovement of the finger) to shift a small amount of content when thenavigation interval is small and to shift a larger amount of contentwhen the navigation interval is large (for a same user device). Forinstance, if a user selects the navigation setting associated with theshifting limit value of 5 min, the scaling parameter is chosen such thata navigation amount corresponding to a path length of a few centimetersnavigates the content by a navigation amount time of a few minutes.Conversely, if a user selects the navigation setting associated with theshifting limit value of 1 h, the scaling parameter is chosen such that asame navigation amount (i.e. corresponding to the path length of a fewcentimeters, on a same user device) navigates the content by anavigation amount time of a few tens of minutes. The user is thus ableto easily and precisely reach the desired shifted play position.

Other approaches and embodiments are disclosed herein. Media contentmanipulation mechanisms, techniques and systems are introduced tofacilitate convenient, rapid and precise navigation of media content.

BRIEF DESCRIPTION OF THE DRAWINGS

The above and other objects and advantages of the disclosure will beapparent upon consideration of the following detailed description, takenin conjunction with the accompanying drawings, in which like referencecharacters refer to like parts throughout, and in which:

FIG. 1 is an illustrative diagram of a graphical interface fornavigating content, according to some embodiments of the disclosure;

FIG. 2 is another illustrative diagram of a graphical interface fornavigating content, according to some embodiments of the disclosure;

FIG. 3 is an illustrative topology of equipment (or computingconfiguration) programmed and configured for navigating content,according to some embodiments of the disclosure;

FIG. 4 is an illustrative flowchart of a process for navigating content,according to some embodiments of the disclosure;

FIGS. 5A, 5B, 5C, and 5D are illustrative diagrams of the boundaries ofthe navigation intervals, according to some embodiments of thedisclosure;

FIGS. 6A, 6B, and 6C are illustrative diagrams of the navigationintervals and the shifting limit values, according to some embodimentsof the disclosure;

FIG. 7 is an illustrative diagram of a plurality of navigation settings,according to some embodiments of the disclosure;

FIG. 8 is an illustrative flowchart of a process for computing thenavigation interval, according to some embodiments of the disclosure;

FIGS. 9A and 9B are illustrative diagrams of two different scalingparameters, according to some embodiments of the disclosure;

FIG. 10 is an illustrative flowchart of a process for computing anavigation amount time using a scaling parameter, according to someembodiments of the disclosure;

FIGS. 11A and 11B are illustrative diagrams representing visual markersto assist the user, according to some embodiments of the disclosure;

FIG. 12 is an illustrative flowchart of a process for generating fordisplay the visual markers, according to some embodiments of thedisclosure;

FIG. 13 is an illustrative diagram of 2-dimensional path relating to thenavigation amount, according to some embodiments of the disclosure;

FIG. 14 is an illustrative flowchart of a process for navigating withinthe navigation interval using a path, according to some embodiments ofthe disclosure.

DETAILED DESCRIPTION

In an aspect of the disclosure, systems and methods implement aninterface for content navigation. The interface is configured to detectactivation of a navigation process using the interface, display aplurality of navigation settings associated with navigation intervalswithin the content, detect selection of one navigation setting, detectan input relating to a navigation amount, and navigate within theselected navigation interval based on the navigation amount.

FIGS. 1 and 2 are illustrations of a graphical user interface fornavigating content based on a navigation interval, according to someembodiments of the disclosure. A content navigation system may detect,in a content display interface 100 of a user device 102 (smartphone,tablet, etc.), an input 104 to perform a content navigation operation ina media content 106 that is being viewed by a user. For instance, theinput 104 may be the user clicking or tapping, using the content displayinterface 100, on a current play position 108 on a seekbar 110associated with the content 106.

In response to that detection, the content navigation system generatesfor display, on the content display interface 100, a plurality ofselectable navigation settings 110 a, 110 b. For instance, the displayof the navigation settings 110 a, 110 b may appear overlaid on thecontent being displayed (e.g., with transparency or not). Eachselectable navigation setting 110 a, 110 b may comprise a visualrepresentation to assist the user in differentiating between them, suchas an alphanumerical character (“−”, “+”, “S”, “M” or “Min”, “H” or“Hr”, etc.). Each navigation setting is associated with a shifting limitvalue that determines a navigation interval within the content. Anavigation interval represents a portion of the content in which thecontent navigation system will allow the user to navigate. The portionof the content that is outside the navigation interval is therefore notaccessible to the user via the processes disclosed herein. In thisrespect, the time shifting limits are set so that at least one (andpreferably all) of the navigation intervals of the navigation settingsdoes not encompass the beginning or the end of the content. Thenavigation interval is defined by the shifting limit value and a currentplay position of the content. In addition, the shifting limit values ofthe plurality of navigation settings 110 a, 110 b are set to bedifferent from one another, such that the corresponding navigationintervals are different. A navigation interval is illustrated by meansof its boundaries 202, 204 in FIG. 2 and will be discussed in moredetail below. Typically, one of the shifting limit values is a fewminutes or less, so that the navigation interval spans to a few minutesafter (and/or before) the current play position 204 (e.g., 1 min or 5min) and one of the shifting limit values is a few tens of minutes ormore, so that the navigation interval spans a few tens of minutes after(and/or before) the current play position (e.g., 30 min or 60 min). Theuser is thus given, by the content navigation system, a plurality ofoptions that allow him or her to adapt the navigation process to his orher need, with no risk to navigate to an unwanted portion of thecontent.

As illustrated in FIG. 2, the content navigation system then receives aninput 206, from the user, which indicates a selection of one of theselectable navigation settings 110 a, 110 b (e.g., navigation setting110 b). For instance, the input 206 may be the user clicking or tappingon one of the selectable navigation settings 110 a, 110 b, which aredisplayed on the content display interface 100. As mentioned above, FIG.2 illustrates the navigation interval, by means of its boundaries 202,204 (represented by visual markers at its boundaries on the seekbar),associated with the navigation setting 110 b. Typically, to assist theuser in making his or her choice, the navigation interval may berepresented on the content display interface after reception of theinput 206 (in that case only the navigation interval of the selectednavigation setting is represented) or after reception of the input 104(in that case the navigation intervals of all the selectable navigationsettings are represented). After reception of the input 206, thenon-selected navigation setting(s) may no-longer be displayed or theymight remain on the content display interface in case the user changeshis or her mind, or all the navigation settings may no longer bedisplayed.

The content navigation system further receives an input 208 relative tothe navigation amount within the content display interface 100. Forinstance, the input 208 may be the user dragging his or her finger onthe content display interface 100 from one place to another, therebydefining a physical path (e.g., physically touching the content displayinterface, moving or sliding the finger while keeping contact, andreleasing the finger from the content display interface). The navigationamount may be the length of that path, which may be 2-dimensional, orthe length of a 1-dimensional projection of that path, such as aprojection orthogonal or parallel to the seekbar. Visual markers,discussed in more detail below, may be provided to assist the user indetermining how much navigation amount is desired.

Finally, the content navigation system navigates from the current playposition 108 to a shifted play position 210 based on the navigationamount. A scaling parameter may be used to convert the navigation amountinto a navigation amount time, the navigation amount time being theamount of content between the current play position 108 and the shiftedplay position 210. Per the navigation setting and its associatedshifting limit value, the shifted play position can only be in thenavigation interval (shifted play position 210 is between the boundaries202, 204 of the navigation interval).

FIG. 3 shows an illustrative block diagram of a computing configuration300 that may include the content navigation system disclosed in relationto FIGS. 1 and 2. Computing configuration 300 includes a user device302. In some embodiments, the user device 302 may include controlcircuitry 304 and an input/output (I/O) path 306. Control circuitry 304may include processing circuitry 308, and storage 310 (e.g., RAM, ROM,hard disk, removable disk, etc.). I/O path 306 may provide deviceinformation, or other data, over a local area network (LAN) or wide areanetwork (WAN), and/or other content and data to control circuitry 304.Control circuitry 304 may be used to send and receive commands,requests, signals (digital and analog), and other suitable data usingI/O path 306. I/O path 306 may connect control circuitry 304 (andspecifically processing circuitry 308) to one or more communicationspaths.

User device 302 may include a display 312 and a speaker 314 to displaycontent visually and audibly. In addition, to interact to a user, userdevice 302 includes a user interface 316 (which may be used in relationto the content display interface 100 disclosed herein). The userinterface 316 may include a touchscreen, mouse and/or keyboard. The userinterface 316 is connected to the I/O path 306 and the control circuitry304. In an embodiment, the user interface 316 and the display 312 may bea touchscreen enabling the user to provide input(s) to the user device.The display 312 may a screen (such as a monitor or a TV).

Control circuitry 304 may be based on any suitable processing circuitrysuch as processing circuitry 308. As referred to herein, processingcircuitry should be understood to mean circuitry based on one or moremicroprocessors, microcontrollers, digital signal processors,programmable logic devices, field-programmable gate arrays (FPGAs),application-specific integrated circuits (ASICs), etc., and may includea multi-core processor (e.g., dual-core, quad-core, hexa-core, or anysuitable number of cores) or supercomputer. In some embodiments,processing circuitry may be distributed across multiple separateprocessors or processing units, for example, multiple of the same typeof processing units (e.g., two Intel Core i7 processors) or multipledifferent processors (e.g., an Intel Core i5 processor and an Intel Corei7 processor).

Memory may be an electronic storage device provided as storage 310,which is part of control circuitry 304. Storage 310 may storeinstructions that, when executed by processing circuitry 308, performthe processes described herein. As referred to herein, the phrase“electronic storage device” or “storage device” should be understood tomean any device for storing electronic data, computer software, orfirmware, such as random-access memory, read-only memory, hard drives,solid state devices, quantum storage devices, or any other suitablefixed or removable storage devices, and/or any combination of the same.Nonvolatile memory may also be used (e.g., to launch a boot-up routineand other instructions).

The user device 302 may be a smartphone, a tablet, an e-reader, alaptop, a smart TV, etc.

Computing configuration 300 may also include a communication network 318and a server device 320. The user device 302 may be coupled to thecommunication network 318 to communicate with the server device 320. Thecommunication network 318 may be one or more networks including theInternet, a mobile phone network, mobile voice or data network (e.g., a5G, 4G or LTE network), mesh network, peer-to-peer network, cablenetwork, or other types of communication network or combinations ofcommunication networks.

In some embodiments, server device 320 may include control circuitry 322and an input/output (I/O) path 324. Control circuitry 304 may includeprocessing circuitry 326, and storage 328, which may similar to thosealready discussed in relation to the user device 302. Server device 320may be a content provider for the user device 302, such as a streaming,VOD, replay platform, etc.

In some embodiments, the content navigation system comprises the userdevice 302, whether the content is being streamed from the server orbeing retrieved from the storage 310. Alternatively, the contentnavigation system is distributed over the user device 302 and the serverdevice 320.

FIG. 4 is an illustrative flowchart of a process for navigating content,in accordance with some embodiments of the disclosure. Process 400, andany of the following processes, may be executed by any of controlcircuitry 304 or 322 or any combination thereof, using the communicationnetwork 318. For conciseness reasons, only control circuitry 304 will beused in the following description.

At step 402, control circuitry 304 starts playing content (e.g., a mediaasset such as a video) on display 312.

At step 404, during play of the content, control circuitry 304 detects,via a content display interface, an input to perform a contentnavigation operation. This corresponds to a user wanting to navigatethrough the content, either forward or backward. Detecting the input toperform a content navigation operation may comprise receiving an inputof a selection of a seekbar within the content display interface, theseekbar representing a navigation space throughout the content (from abeginning to an end of the content). For instance, the user might usehis or her finger to tap on the seekbar (e.g., on the current playposition of the seekbar). Detecting the input to perform a contentnavigation operation may comprise receiving an input of a user touchingthe display (e.g., with his or her finger), which may, for instance,cause the seekbar to be displayed. Alternatively, there might be adedicated navigation button available on the content display interface.In an embodiment, control circuitry 304 pauses the content upondetection of the input at step 404. In an embodiment, control circuitry304 keeps on playing the content on display 312.

At 406, control circuitry 304, in response to step 404, generates fordisplay on the content display interface at least two navigationsettings. The two navigation settings may be overlaid on the content, bythe display 312. Those navigation settings are selectable using thecontent display interface, which means that a user is able to pick oneof them. Each navigation setting is associated with a shifting limitvalue which determines, in combination with a current play position, anavigation interval within the content. As indicated above, no twoshifting limit values are identical. This allows the content navigationsystem to provide flexibility to the user. Control circuitry 304 mayalso generate for display the seekbar at 406, if not already displayed.

At 408, control circuitry 304 receives an input indicating a selectionof one of the selectable navigation settings. For instance, the usermight use his or her finger to tap on one of the displayed navigationsettings by means of the user interface 316 to interact with the contentdisplay interface that appears on display 312. Upon reception of theinput at 408, control circuitry 304 may retrieve the shifting limitvalue associated with the navigation setting. In addition, uponreception at 408, control circuitry 304 may generate a request to stopdisplaying the navigation settings, to clear the content displayinterface.

At 410, control circuitry 304 receives an input indicating a navigationamount within the content display interface. The navigation amountrepresents how much the user wants to navigate. The navigation amountmay be determined using a path on the content display interface, such asa finger being dragged while in contact. Further detail about the pathswill be given below.

At 412, control circuitry 304, based on the navigation amount previouslyinput at step 408, navigates from the current play position to a shiftedplay position. The shifted play position is located within thenavigation interval that was retrieved from the selected navigationsetting. At 414, control circuitry 304 starts playing of the contentfrom the shifted play position.

In an embodiment, the navigation interval is based on the current playposition and the shifting limit value. The current play position may bethe play position at the time of the input to perform the contentnavigation operation (step 404), or at the time of generating fordisplay the selectable navigation settings (step 406), or at the time ofinput indicating a selection of the navigable settings (step 408), oreven at the time of input pertaining to the navigation amount (412).This depends on whether the content was paused or not at step 404, 406,408, 410 or 412. In practice, it would take only a few seconds from step402 to step 410 such that which current play position is used has nosignificant impact. In one embodiment, the navigation interval may bedynamically computed such that any change in the current play positionimpacts the navigation interval.

FIGS. 5A, 5B, 5C, 6A, 6B, 6C, 6D, and 7 illustrate different embodimentsto determine boundaries of the navigation intervals and how thenavigation intervals may be computed. FIG. 7 shows a flowchart for aprocess to determine the navigation intervals.

FIGS. 5A, 5B, 5C and 5D illustrate, using a seekbar 500, differentconfigurations for the boundaries of the navigation interval. In animplementation illustrated in FIG. 5A, the navigation interval 502 a isdetermined by the current play position 504 a (left boundary of thenavigation interval on the seekbar 500) and the current play positionplus the shifting limit value 506 a (right boundary of the navigationinterval on the seekbar 500). In this case, the navigation system isconfigured to ease a forward navigation only. In an implementationillustrated in FIG. 5B, the navigation interval 502 b is determined bythe current play position minus the shifting limit value 504 b (leftboundary of the navigation interval on the seekbar 500) and the currentplay position 506 b (right boundary of the navigation interval on theseekbar 500). In that case, the navigation system is configured to easea backward navigation only. In an implementation illustrated in FIG. 5C,the navigation interval 502 c is determined by the current play positionminus the shifting limit value 504 c (left boundary of the navigationinterval on the seekbar 500) and the current play position plus theshifting limit value 506 c (right boundary of the navigation interval onthe seekbar 500). In this case, the navigation system is configured toease a backward and forward navigation. The navigation interval 502 cis, in that implementation, centered on the current play position 508.That a navigation interval is for forward navigation, backwardnavigation, or both (irrespective of the shifting limit value as such)may vary between the selectable navigation settings displayed at step406 (FIG. 4), such that one selectable navigation setting may be used tonavigate forward only and another one backward only. In animplementation illustrated in FIG. 5D, each the navigation setting (orat least one) may be associated with a backward shifting limit value anda forward shifting limit value, such that the navigation interval 502 dis determined by the current play position minus the backward shiftinglimit value 504 d (left boundary of the navigation interval on theseekbar 500) and the current play position plus the forward shiftinglimit value 506 d (right boundary of the navigation interval on theseekbar 500). Navigation interval 502 d is thus not centered on thecurrent play position 508. All these possibilities for the navigationsettings allow the navigation content system to be more adaptable. Thedisclosed embodiments can be combined among the plurality of navigationsettings.

FIGS. 6A, 6B, and 6C illustrate different configurations for theshifting limit values. These illustration are made using a seekbar 600representing content with a beginning 602 and an end 604 and beingdisplayed at a current play position 606. The shifting limit value maybe a relative shifting limit value, determined by taking into accounteither the overall length of the content or the time elapsed or left toview. The shifting limit value may alternatively be an absolute shiftinglimit value, determined independently from the overall length of thecontent (e.g., predetermined and stored in the storage 310).

FIG. 6A illustrates two navigation settings 608 a, 610 a with theirrespective navigation intervals 612 a, 614 a determined by theirrespective shifting limit values. In this case, the two shifting limitvalues are absolute, which means that the spans of the navigationintervals 612 a, 614 a do not depend on the overall length of thecontent (i.e., the time between the beginning 602 and the end 604) orthe time of content elapsed or left to watch (i.e., the time between thebeginning 602 and the current play position 606, or the time between thecurrent play position 606 and the end 604). Therefore, regardless of thecurrent play position 606, the navigation intervals 612 a, 614 a willhave the same spans. For example, the shifting limit value of navigationsettings 608 a may be 5 min, and the shifting limit value of navigationsetting 610 a may be 1 h. More generally, for a couple of navigationsettings, one of the shifting limit values may be between 30 s and 5 min(e.g., 1 min) and one of the shifting limit values may be between 45 minand 1 h30 (e.g., 1 h).

FIG. 6B and 6C illustrate two navigation settings 608 b, 610 b and 608c, 610 c with their respective navigation intervals 612 b, 614 b and 612c, 614 c determined by their respective shifting limit values. The twoshifting limit values here are relative, which means that the spans ofthe navigation intervals 612 b, 614 b and 612 c, 614 c do depend on theoverall length of the content or the time elapsed or left to view. Inthe embodiment of FIG. 6B, the shifting limit values may be determinedas a fraction of the content left to view 616 b, that is to say, theamount of content between the end 604 and the current play position 606.For example, the shifting limit value of navigation settings 608 b maybe 10% of the content left to view 616 b, and the shifting limit valueof navigation setting 610 b may be 50% of the content left to view 616 b(halfway through the content left to view). More generally, for a coupleof navigation settings, one of the shifting limit values may be between1% and 15% (e.g., 10%) of the content left to view 616 b and one of theshifting limit values may be between 40% and 70% (e.g., 50%) of thecontent left to view 616B. In the embodiment of FIG. 6C, the shiftinglimit values may be determined using a fraction of the overall length ofthe content 616 c and the current play position, such that thenavigation interval is the amount between those two positions. Forexample, the fraction of the overall length of the content 616 c may be80% or the number of hours of the content (e.g., 2 h for a 2 h32min-long content or 1 h for a 1 h08 min-long content), such that thenavigation interval 612C or 614C is defined by the current play positionon one boundary, and the 80% of the overall content or the number ofhours of the content on the other boundary. In this embodiment, it isobservable that the position of the boundary of the navigation intervalthat is not the current play position is independent from the currentplay position (because it is defined in relation to the overall lengthof the content only).

In FIGS. 6A, 6B, and 6C, the navigation intervals were determined asdefined in relation to FIG. 5A only for conciseness reason (i.e., thenavigation interval is between the current play position and the currentplay position plus the time shifting value). The navigation intervalscan be also determined as defined in relation to FIG. 5B, 5C, and 5D. Inparticular, in the implementation of FIG. 5D, for each navigationsetting, the fraction associated with the forward shifting limit valueand the backward shifting limit value may be identical (e.g., 50%) ordifferent (e.g., 40% and 60%).

The embodiments to determine the navigation intervals (absolute orrelative shifting limit value) may be combined among the plurality ofnavigation settings. For instance, one navigation setting of theplurality of selectable navigation settings may be associated withabsolute shifting limit value as detailed above and another navigationsetting of the plurality of selectable navigation setting may beassociated with a relative shifting limit value as detailed above. Inone particular implementation illustrated in FIG. 7, using a seekbar 700at a current play position 702, the plurality of selectable navigationsettings includes three navigation settings 704, 706, 708. A firstnavigation setting 704 is associated with an absolute shifting limitvalue that is between 30 s and 5 min (e.g., 1 min), a second navigationsetting 706 is associated with an absolute shifting limit value that isbetween 30 min and 1 h30 min (e.g., 1 h), and a third navigation setting708 is associated with a navigation interval whose boundary is thenumber of hours of the content (e.g., 1 h for any content whose overalllength is between 1 h and 1 h59 min59 s, 2 h for any content whoseoverall length is between 2 h and 3 h59 min59 s, etc.). The respectivenavigation intervals are referenced 710, 712 and 714.

FIG. 8 is an illustrative flowchart of a process 800 to determine thenavigation interval, in accordance with some embodiments of thedisclosure. Process 800 may be performed during step 406 of generatingfor display at least two navigation settings, or in response to step404.

At step 802, control circuitry 304 retrieves the current play positionand, at step 804, control circuitry 304 determines whether thenavigation setting is associated with an absolute shift value or arelative shift value. Steps 802 and 804 can be run in parallel or in anyorder. In response to determining that the shifting limit value isabsolute, control circuitry retrieves, at 806, the shifting limit valueassociated with the selected navigation setting (even though theselectable navigation settings are not yet displayed) and, at 810,computes the navigation intervals as disclosed in relation to FIG. 6A.In response to determining that the shifting limit value is relative,control circuitry retrieves, at 808, the overall length of the contentand, at 810, computes the navigation intervals as disclosed in relationto FIG. 6B and 6C.

When using absolute shifting limit values, it may happen that thenavigation interval of a selectable navigation setting reaches thebeginning or the end of the content and, thus, falls outside thecontent. As illustrated in the flowchart of FIG. 8, after havingcomputed the navigation intervals, control circuitry 304 may, at 812,determine whether the respective computed navigation intervals of thenavigation settings fall within the content, and at 814, controlcircuitry 304 generates for display only the navigation settings forwhich the navigation intervals fall within the content. Step 814 maytherefore correspond to step 406 in an embodiment. For instance, thecontent navigation system may have, in the storage 310, a plurality ofnavigation setting configurations and display a selection of two orthree of them that fall within the content.

In an embodiment, to further ease the navigation, control circuitry 304may utilize a scaling parameter, the scaling parameter being the linkbetween the navigation amount (of step 410) and the navigation amounttime within the navigation interval (i.e., the amount of content that isbeing shifted based on the navigation amount). For instance, assumingthat the navigation amount is a distance D, for instance the length of apath drawn by a finger on the user interface 316, and that thenavigation amount time T within the content is proportional to thedistance D, then D and T can be expressed as: T=k.D, where k is thescaling parameter (only positive numbers are considered here). For asame distance D, the higher k is, the higher T is.

FIGS. 9A and 9B illustrate, using a seekbar 900 and a current playposition 902, two situations where the scaling parameters are different.In FIGS. 9A and 9B, the navigation intervals, respectively representedby the boundaries 902 and 904 a, 902 and 904 b, do not have the samelength (much longer in FIGS. 9A than in FIG. 9B). However, to be able tonavigate easily, it is preferable that the movement associated with aninput of a navigation amount 906 be easily doable by a user. Typically,the input may include a path on the content interface displayrepresenting a navigation amount 906. As such, the navigation amount 906may be physically limited (e.g., the maximum dimension of the contentinterface display, which is usually the height or the width of thedisplay of the user device) or reasonably limited by the effort that theuser is ready to put into the navigation process. Therefore, to be ableto navigate throughout the whole navigation intervals of FIGS. 9A and9B, while keeping some precision in the shifted position, the scalingparameter needs to be adapted to the span of the navigation interval. InFIG. 9A, the navigation interval has a length of approximately 1 h andin FIG. 9B, the navigation interval has a length of approximately 10min. In both FIGS. 9A and 9B, the navigation amount is around 4 cm. Tobe able to navigate throughout the navigation interval of FIG. 9A withthe navigation amount 906, the scaling parameter needs to be big (ataround 15 min/cm), while to be able to navigate finely throughout thenavigation interval of FIG. 9B with the same navigation amount 906, thescaling parameter needs to be small (at around 3 min/cm). Therefore, fora same navigation amount 906, the shifted position 908 a in FIG. 9A isfarther away from the current play position than the shifted position908 b in FIG. 9B.

FIG. 10 is an illustrative flowchart of a process 1000 taking intoaccount a scaling parameter. At step 1002, control circuitry 304 obtainsa scaling parameter. Step 1002 can be performed anytime between steps404 and 412. Then, using the navigation amount of step 410 and thescaling parameter, control circuitry 304 computes, at 1004, thenavigation amount time and, at 1006, navigates within the navigationinterval based on the navigation amount time.

In an embodiment, the scaling parameter is part of the navigationsettings, such that each navigation setting is associated with ashifting limit value and a scaling parameter. Therefore, obtaining ascaling parameter 1002 may be based on the selection of the navigationsettings, at 408.

To improve the navigation, the scaling parameters of the plurality ofnavigation settings are different from one another and are chosen to berelevant for the navigation interval of their respective navigationsetting. As explained above, for instance, a navigation interval of 1min may need a small scaling parameter, so that the user can finelyadjust the shifted position using a substantial portion of the contentdisplay interface. Conversely, a navigation interval of 2 h may need ahigh scaling parameter, so that the user may easily adjust the shiftedposition using the same substantial portion of the content displayinterface.

To get the most appropriate scaling parameter, control circuitry 304 maycompute the scaling parameter as follows: span of the navigationinterval divided by a dimension of the content display interface (e.g.,the height, the width, or the diagonal of the display of the userdevice). A scaling parameter computed this way is therefore defined as afunction of the navigation interval associated with a setting parameter,and thus, is appropriate to easily navigate throughout the navigationinterval. For instance, if a user selects a navigation settinggenerating a navigation interval of one minute after the current playposition in a content that is 3 h, the user can take advantage of thewhole display of his or her device to finely navigate within thatminute, instead of struggling to move the play position on the seekbaras little as possible (which, in that situation, might already be toomuch given the length of the content) per the existing techniques. Inthis regard, control circuitry 304 may compute the scaling parameterafter step 404 if the current play position is needed. For instance, thecontrol circuitry 304 may compute the scaling parameter after receptionof the input indicating a selection, at step 408.

In addition, control circuitry 304 may display, on the content displayinterface, an option for the user to voluntarily change the scalingparameter. Upon input from a user, control circuitry 304 may thencompute the navigation amount time using the voluntarily changed scalingparameter.

To assist the user in navigating within the content, the navigationsystem may display different types of visual markers on the contentdisplay interface (or the display of the user device). FIGS. 11A and 11Billustrates different visual markers, using a seekbar 1100 and currentplay position 1102.

In an embodiment illustrated in FIGS. 11A and 11B, a visual marker mayrepresent each navigation interval, for instance by showing theboundaries 1104 (only one navigation interval represented in FIG. 11A).Control circuitry 304 may generate for display that visual marker at thesame time it generates for display the selectable navigation settings.After step 410 of reception of an input indicating a selection of anavigation setting, only the visual marker associated with navigationinterval of the selected navigation setting may be displayed.

In another embodiment illustrated in FIG. 11A, a visual marker may be athumbnail 1106 (or preview window) representing the (or of the) contentat the shifted position 1108 or may be a marker 1108 (the same referenceof 1108 is used here to designate both the shifted position and itsvisual indication on the content display interface) of the expectedshifted position. The thumbnail and/or the marker of the expectedshifted position may appear only at the end of the input of thenavigation amount or, preferably, while the user is currently inputtingthe navigation amount, so that he or she gets a real-time preview of thecontent. Preferably, the thumbnail is in the vicinity of the seekbar.Control circuitry 304 may generate for display that visual marker at thesame time it is receiving the input of the navigation amount.

In an embodiment illustrated in FIG. 11A, a visual marker may be anelapsed time indication 1110 of the shifted position in the content, forinstance in the form of a sequence “h:min:s” corresponding to the timeposition of the shifted position in the content (e.g., “1 h25 min12 s”as illustrated in FIG. 11A, while the current play position may be, forinstance,

“0 h53 min22 s”). The time indication may appear only at the end of theinput of the navigation amount or while the user is currently inputtingthe navigation amount, so that he or she gets a real-time timeindication of the shifted position. Preferably, the time indication isin the vicinity of the input on the content display interface (e.g.,where the finger is). Control circuitry 304 may generate for displaythat visual marker at the same time it is receiving the input of thenavigation amount.

In an embodiment illustrated in FIG. 11A, a visual marker may be asetting marker 1112 of a selectable navigation setting 1114. The settingmarker 1112 provides some information to the user about the selectablenavigation setting 1114: it may be an alphanumeric character or seriesof characters, or an illustration. In one implementation, eachnavigation setting 1114 has its own setting marker 1112, and they aredifferent from one another. For instance, the setting marker 1112differentiates based on the length of the associated navigation interval(illustrated by boundaries 1104). An example of different of settingmarkers is provided in FIG. 7, where “Sec”, “Min” and “Hour” indicate tothe user an order of magnitude of the navigation authorized by theassociated navigation setting. Setting marker 1114 may appear anddisappear on the content display interface at the same time that theselectable navigation setting may appear and disappear. Controlcircuitry 304 may thus generate for display that visual marker at thesame time control circuitry 304 is generating for display the selectablenavigation settings. In addition, each selectable navigation setting,when generated for display, may comprise a visual button overlaid on thecontent, with transparency or not (e.g., the circles in FIGS. 1, 2, 6A,6B, 6C, 7, 11A), on which the user may click to provide the inputdefined in step 408.

In an embodiment illustrated in FIG. 11B, a visual marker may includetemporal markers representing different temporal positions 1116 withinthe content (or more specifically within the navigation interval)represented by the seekbar. The time indications 1116 may mark every 10s, 30 s, 1 min, 5 min, 15 min, 30 min, or 1 h, for instance (or anyother value at regular intervals). The temporal positions 1116 mayappear during the input of the navigation amount or at the same time asthe generation for display of the navigation settings, at step 406.

FIG. 12 is an illustrative flowchart of a process 1200 displaying visualmarkers. After step 406 (or at the same time) and before step 408,control circuitry 304 may generate for display, at 1202, a first visualmarker. The first visual marker may be the setting marker 1112, theboundaries 1104 and/or the temporal position 1116. During or after step410 (reception of input about the navigation amount), control circuitry304 may generate for display, at 1204, a second visual marker. Thesecond visual marker may be the thumbnail 1106, the marker 1108, or thetime indication 1110, for instance in addition to the first visualmarker. Once the navigation to the shifted position is done, at 412,control circuitry 304 may, at 1206, remove all the visual markers fromthe content display interface (including the seekbar or any otherinformation displayed).

As illustrated in FIGS. 2, 9A and 9B, and 13, the navigation amount maycomprise a path within the content display interface. The navigationamount is typically determined using a path on the content displayinterface, via the user interface 316. For instance, in FIG. 13, a path1302 starts with the detection of a physical touching 1304 of thecontent display interface and terminates with the detection of a release1306 of the physical touching of the content display interface. Thephysical touching may be performed by a finger or a stylus. The path maybe essentially 1-dimensional, as illustrated in FIGS. 2, 9A and 9B (eventhough a user cannot usually perform a perfectly straight line and thepath will inherently be 2-dimensional), or 2-dimensional, as illustratedin FIG. 13.

To convert the path into a navigation amount that can be used by thecontent navigation system, a length of the path may be computed. In oneembodiment, the navigation amount is the overall length of the path.When the path is a 2-dimensional path, a 2-dimensional grid may be usedto compute the length of the path. Using a 2-dimensional path, thelength of the path may include at least one loop 1308 to increase itslength (e.g., a finger going 3 cm to the right then 1 cm to the leftmeans the path has a length of 4 cm). Therefore, the user might not needto use a whole dimension of the content display interface to input thepath, but can easily do it on a small, localized portion of the contentdisplay interface, doing loops or similar shapes. In one embodiment, thenavigation amount is the length of the path going in one direction, suchas left and right (e.g., a finger going 3 cm to the right then 1 cm tothe left means the path has a length of 2 cm to the right and not alength of 4 cm). This allows movement forward and backward based on thedirection of the path. In this case, the loop would have a null effect(or close to null) on the length of the path. In one embodiment, thenavigation amount is the length of a 1-dimensional projection 1310 ofthe 2-dimensional path (e.g., a projection orthogonal to the seekbar orparallel with the seekbar). In one embodiment, the navigation amount isthe length of the projection of the path based on the direction of thepath, such as left and right (e.g., a projection, of a path, going 3 cmto the right then 1 cm to the left means the projection of the path hasa length of 2 cm to the right).

FIG. 14 is an illustrative flowchart of a process 1400 where thenavigation amount is determined based on a path on the content displayinterface. After step 408, control circuitry 304 may receive, at 1402,an input indicating a path within the content display interface. Step1402 may comprise detecting, at 1404, a physical touching of the contentdisplay interface and detecting, at 1406, the release of the physicaltouching to terminate the path. In one implementation, the detection, atstep 1404, is the reception of the input indicating a selection of anavigation setting, at step 408, so that the user chooses the navigationsetting, and, during the same movement of the hand or finger, proceedswith the path, determining the navigation amount. At 1408, controlcircuitry 304 determines a length associated with the path. As describedabove, the length may be the overall length of the path, a portion ofthe overall length of the path, or the length of a projection of thepath. Finally, at 1410, corresponding to step 412, control circuitry 304navigates within the navigation interval based on the determined length.This is typically performed using the scaling parameter disclosedpreviously to link the path length (i.e., the navigation amount) withthe navigation amount time.

In a further embodiment, control circuitry 304 may determine a forwardor backward direction for the content navigation operation. Thedetection may occur while receiving an input indicating a selection of anavigation setting, at 408, or may be independent. In oneimplementation, the determination may be based on detecting an initialforward or reverse navigation motion within the content displayinterface, for instance, just after detection of the physical touching,at 1404, using the direction of the beginning of the path.

The above-described embodiments of the present disclosure are presentedfor purposes of illustration and not of limitation, and the presentdisclosure is limited only by the claims that follow. Furthermore, itshould be noted that the features and limitations described in any oneembodiment may be applied to any other embodiment herein, and flowchartsor examples relating to one embodiment may be combined with any otherembodiment in a suitable manner, done in different orders, or done inparallel. In addition, the systems and methods described herein may beperformed in real time. It should also be noted, the systems and/ormethods described above may be applied to, or used in accordance with,other systems and/or methods.

1. A method for navigating content, the method comprising: generatingfor display, on a content display interface, at least two selectablenavigation settings, wherein each navigation setting is associated witha shifting limit value that determines, in combination with a currentplay position, a navigation interval within the content, the shiftinglimit values of the at least two selectable navigation settings beingdifferent from one another; receiving an input indicating a selection ofone of the selectable navigation settings; receiving an input indicatinga navigation amount within the content display interface; and navigatingfrom a current play position to a shifted play position within thenavigation interval based on the selected navigation setting and thenavigation amount.
 2. The method of claim 1, further comprisingutilizing a scaling parameter, the scaling parameter translating thenavigation amount to a navigation amount time, wherein navigating fromthe current play position to the shifted play position is further basedon the scaling parameter.
 3. The method of claim 2, wherein eachselectable navigation setting is associated with a corresponding scalingparameter, and utilizing a scaling parameter is based on the selectionof the navigation setting.
 4. The method of claim 1, wherein thenavigation interval is determined by: the current play position and thecurrent play position plus the shifting limit value; or the current playposition minus the shifting limit value and the current play positionplus the shifting limit value; or the current play position minus theshifting limit value and the current play position.
 5. The method ofclaim 1, wherein at least one of the shifting limit values is determinedbased on a predetermined absolute value, or on the amount of contentleft to view or on the overall length of the content.
 6. The method ofclaim 1, wherein the at least two selectable navigation settingsinclude: a first selectable navigation setting associated with a firstshifting limit value between 30 seconds and 5 minutes; a secondselectable navigation setting associated with a second shifting limitvalue between 30 minutes and 1 hour and 30 minutes; a third selectablenavigation setting associated with a navigation interval whose extremityis the number of hours of the content.
 7. The method of claim 1, furthercomprising displaying on the content display interface at least one of:an interval marker representing the navigation interval; a previewwindow representing the content at the shifted play position; an elapsedtime indication of the shifted play position; wherein the contentdisplay interface includes a seekbar, temporal markers indicatingpositions within the content represented by the seekbar; and wherein thecontent display interface includes a seekbar, a marker representing anexpected shift position during the reception of the input of thenavigation amount.
 8. The method of claim 7, wherein the content displayinterface includes a seekbar, wherein the preview window is displayed onthe seekbar and/or the shifted play position time value is displayed inthe vicinity of the input indicating the navigation amount.
 9. Themethod of claim 1, wherein the input indicating the navigation amountincludes a physical path within the content display interface.
 10. Themethod of claim 9, wherein the physical path is based on detecting aphysical touching, sliding along and release from the content displayinterface and wherein the detection of the physical touching is thereception of the input indicating the selection of the selectablenavigation setting.
 11. A system for navigating content, the systemcomprising: control circuitry configured to: generate for display, on acontent display interface, at least two selectable navigation settings,wherein each navigation setting is associated with a shifting limitvalue that determines, in combination with a current play position, anavigation interval within the content, the shifting limit values of theat least two selectable navigation settings being different from oneanother; receive an input indicating a selection of one of theselectable navigation settings; receive an input indicating a navigationamount within the content display interface; and navigate from a currentplay position to a shifted play position within the navigation intervalbased on the selected navigation setting and the navigation amount. 12.The system of claim 11, wherein the control circuitry is furtherconfigured to: utilize a scaling parameter, the scaling parametertranslating the navigation amount to a navigation amount time; whereinnavigating from the current play position to the shifted play positionis further based on the scaling parameter.
 13. The system of claim 12,wherein each selectable navigation setting is associated with acorresponding scaling parameter, and utilizing a scaling parameter isbased on the selection of the navigation setting.
 14. The system ofclaim 11, wherein the navigation interval is determined by: the currentplay position and the current play position plus the shifting limitvalue; the current play position minus the shifting limit value and thecurrent play position plus the shifting limit value; or the current playposition minus the shifting limit value and the current play position.15. The system of claim 11, wherein at least one of the shifting limitvalues is determined based on a predetermined absolute value, or on theamount of content left to view or on the overall length of the content.16. The system of claim 11, wherein the at least two selectablenavigation settings include: a first selectable navigation setting isassociated with a first shifting limit value between 30 seconds and 5minutes; a second selectable navigation setting is associated with asecond shifting limit value between 30 minutes and 1 h and 30 min; athird selectable navigation setting is associated with a navigationinterval whose extremity is the number of hours of the content.
 17. Thesystem of claim 11, wherein the control circuitry is further configuredto: display on the content display interface at least one visual markerincluding at least one of: an interval marker representing thenavigation interval; a preview window representing the content at theshifted play position; an elapsed time indication of the shifted playposition; wherein the content display interface includes a seekbar,temporal markers indicating positions within the content represented bythe seekbar; and wherein the content display interface includes aseekbar, a marker representing an expected shift position during thereception of the input of the navigation amount.
 18. The system of claim17, wherein the content display interface includes a seekbar, whereinthe preview window is displayed on the seekbar and/or the shifted playposition time value is displayed in the vicinity of the input indicatingthe navigation amount.
 19. The system of claim 11, wherein the inputindicating the navigation amount includes a physical path within thecontent display interface.
 20. The system of claim 19, wherein thephysical path is based on detecting a physical touching, sliding alongand release from the content display interface and wherein the detectionof the physical touching is the reception of the input indicating theselection of the selectable navigation setting.